Fast Melting and Refining of Recycled Silicon Powders from the Wafer Back Grinding Process for Solar Cell Feedstock

Kum Hee Seo; Bok Hyun Kang; Ki Young Kim

doi:10.4028/www.scientific.net/MSF.706-709.859

Paper Titles

Microstructural Investigation on Tungsten for Applications in Future Nuclear Fusion Reactors
p.835

Effect of Tempering on Mechanical Properties and Microstructure of a 9% Cr Heat Resistant Steel
p.841

Effect of Boron on Microstructure and Impact Toughness of a 10%Cr Martensitic Steel
p.847

A Differential Scanning Calorimetry (DSC) Study of Phase Changes in an As-Received Zr-2.5Nb Pressure Tube Material during Continuous Heating and Cooling
p.853

Fast Melting and Refining of Recycled Silicon Powders from the Wafer Back Grinding Process for Solar Cell Feedstock
p.859

Evolution of Intermetallic Phase Fe2(W, Mo) in 9% Cr Steel during Creep Rupture Tests at 650°C
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Accelerated Microstructure Transformation Caused by Thermal-Mechanical Fatigue
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Structural Changes of Liquid Pb-Bi Eutectic Alloy
p.878

Pulsed Laser Deposition of Pseudocapacitive Metal Oxide Thin Films for Supercapacitor Applications
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HomeMaterials Science ForumMaterials Science Forum Vols. 706-709Fast Melting and Refining of Recycled Silicon...

Fast Melting and Refining of Recycled Silicon Powders from the Wafer Back Grinding Process for Solar Cell Feedstock

Abstract:

A new way to melt and refine recycled silicon powders from the wafer back grinding wastes was proposed. We designed a new equipment using induction heating for the fast melting and directional solidification of the recycled silicon powders, and investigated the feasibility of utilizing them as silicon feedstock for solar cells through lab-scale experiments on the melting and refining them. Silicon particles recovered from back grinding slurry were flake like and very fine, about 3um and was covered with very thin silicon oxide. Slag was observed on the top of the melt during melting, which was composed of oxygen, silicon and carbon which was believed to come from the graphite crucible. Complete melting and subsequent feeding of powders into the melt were prevented by the slag formed during melting, which could be solved by changing the melting atmosphere. Slow growth rate made the impurities such as Al, Ti, Fe, Zr segregate to the top of the ingot purifying the lower part. Over 5N purity was obtained in the middle and lower part of the ingot by the fast melting and directional solidification.